Java Code Examples for sun.awt.geom.Curve#insertMove()

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Example 1
Source File: Area.java    From jdk8u-jdk with GNU General Public License v2.0 4 votes vote down vote up
private static Vector pathToCurves(PathIterator pi) {
    Vector curves = new Vector();
    int windingRule = pi.getWindingRule();
    // coords array is big enough for holding:
    //     coordinates returned from currentSegment (6)
    //     OR
    //         two subdivided quadratic curves (2+4+4=10)
    //         AND
    //             0-1 horizontal splitting parameters
    //             OR
    //             2 parametric equation derivative coefficients
    //     OR
    //         three subdivided cubic curves (2+6+6+6=20)
    //         AND
    //             0-2 horizontal splitting parameters
    //             OR
    //             3 parametric equation derivative coefficients
    double coords[] = new double[23];
    double movx = 0, movy = 0;
    double curx = 0, cury = 0;
    double newx, newy;
    while (!pi.isDone()) {
        switch (pi.currentSegment(coords)) {
        case PathIterator.SEG_MOVETO:
            Curve.insertLine(curves, curx, cury, movx, movy);
            curx = movx = coords[0];
            cury = movy = coords[1];
            Curve.insertMove(curves, movx, movy);
            break;
        case PathIterator.SEG_LINETO:
            newx = coords[0];
            newy = coords[1];
            Curve.insertLine(curves, curx, cury, newx, newy);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_QUADTO:
            newx = coords[2];
            newy = coords[3];
            Curve.insertQuad(curves, curx, cury, coords);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_CUBICTO:
            newx = coords[4];
            newy = coords[5];
            Curve.insertCubic(curves, curx, cury, coords);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_CLOSE:
            Curve.insertLine(curves, curx, cury, movx, movy);
            curx = movx;
            cury = movy;
            break;
        }
        pi.next();
    }
    Curve.insertLine(curves, curx, cury, movx, movy);
    AreaOp operator;
    if (windingRule == PathIterator.WIND_EVEN_ODD) {
        operator = new AreaOp.EOWindOp();
    } else {
        operator = new AreaOp.NZWindOp();
    }
    return operator.calculate(curves, EmptyCurves);
}
 
Example 2
Source File: Area.java    From jdk8u-dev-jdk with GNU General Public License v2.0 4 votes vote down vote up
private static Vector pathToCurves(PathIterator pi) {
    Vector curves = new Vector();
    int windingRule = pi.getWindingRule();
    // coords array is big enough for holding:
    //     coordinates returned from currentSegment (6)
    //     OR
    //         two subdivided quadratic curves (2+4+4=10)
    //         AND
    //             0-1 horizontal splitting parameters
    //             OR
    //             2 parametric equation derivative coefficients
    //     OR
    //         three subdivided cubic curves (2+6+6+6=20)
    //         AND
    //             0-2 horizontal splitting parameters
    //             OR
    //             3 parametric equation derivative coefficients
    double coords[] = new double[23];
    double movx = 0, movy = 0;
    double curx = 0, cury = 0;
    double newx, newy;
    while (!pi.isDone()) {
        switch (pi.currentSegment(coords)) {
        case PathIterator.SEG_MOVETO:
            Curve.insertLine(curves, curx, cury, movx, movy);
            curx = movx = coords[0];
            cury = movy = coords[1];
            Curve.insertMove(curves, movx, movy);
            break;
        case PathIterator.SEG_LINETO:
            newx = coords[0];
            newy = coords[1];
            Curve.insertLine(curves, curx, cury, newx, newy);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_QUADTO:
            newx = coords[2];
            newy = coords[3];
            Curve.insertQuad(curves, curx, cury, coords);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_CUBICTO:
            newx = coords[4];
            newy = coords[5];
            Curve.insertCubic(curves, curx, cury, coords);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_CLOSE:
            Curve.insertLine(curves, curx, cury, movx, movy);
            curx = movx;
            cury = movy;
            break;
        }
        pi.next();
    }
    Curve.insertLine(curves, curx, cury, movx, movy);
    AreaOp operator;
    if (windingRule == PathIterator.WIND_EVEN_ODD) {
        operator = new AreaOp.EOWindOp();
    } else {
        operator = new AreaOp.NZWindOp();
    }
    return operator.calculate(curves, EmptyCurves);
}
 
Example 3
Source File: Area.java    From jdk-1.7-annotated with Apache License 2.0 4 votes vote down vote up
private static Vector pathToCurves(PathIterator pi) {
    Vector curves = new Vector();
    int windingRule = pi.getWindingRule();
    // coords array is big enough for holding:
    //     coordinates returned from currentSegment (6)
    //     OR
    //         two subdivided quadratic curves (2+4+4=10)
    //         AND
    //             0-1 horizontal splitting parameters
    //             OR
    //             2 parametric equation derivative coefficients
    //     OR
    //         three subdivided cubic curves (2+6+6+6=20)
    //         AND
    //             0-2 horizontal splitting parameters
    //             OR
    //             3 parametric equation derivative coefficients
    double coords[] = new double[23];
    double movx = 0, movy = 0;
    double curx = 0, cury = 0;
    double newx, newy;
    while (!pi.isDone()) {
        switch (pi.currentSegment(coords)) {
        case PathIterator.SEG_MOVETO:
            Curve.insertLine(curves, curx, cury, movx, movy);
            curx = movx = coords[0];
            cury = movy = coords[1];
            Curve.insertMove(curves, movx, movy);
            break;
        case PathIterator.SEG_LINETO:
            newx = coords[0];
            newy = coords[1];
            Curve.insertLine(curves, curx, cury, newx, newy);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_QUADTO:
            newx = coords[2];
            newy = coords[3];
            Curve.insertQuad(curves, curx, cury, coords);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_CUBICTO:
            newx = coords[4];
            newy = coords[5];
            Curve.insertCubic(curves, curx, cury, coords);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_CLOSE:
            Curve.insertLine(curves, curx, cury, movx, movy);
            curx = movx;
            cury = movy;
            break;
        }
        pi.next();
    }
    Curve.insertLine(curves, curx, cury, movx, movy);
    AreaOp operator;
    if (windingRule == PathIterator.WIND_EVEN_ODD) {
        operator = new AreaOp.EOWindOp();
    } else {
        operator = new AreaOp.NZWindOp();
    }
    return operator.calculate(curves, EmptyCurves);
}
 
Example 4
Source File: Area.java    From jdk8u-jdk with GNU General Public License v2.0 4 votes vote down vote up
private static Vector pathToCurves(PathIterator pi) {
    Vector curves = new Vector();
    int windingRule = pi.getWindingRule();
    // coords array is big enough for holding:
    //     coordinates returned from currentSegment (6)
    //     OR
    //         two subdivided quadratic curves (2+4+4=10)
    //         AND
    //             0-1 horizontal splitting parameters
    //             OR
    //             2 parametric equation derivative coefficients
    //     OR
    //         three subdivided cubic curves (2+6+6+6=20)
    //         AND
    //             0-2 horizontal splitting parameters
    //             OR
    //             3 parametric equation derivative coefficients
    double coords[] = new double[23];
    double movx = 0, movy = 0;
    double curx = 0, cury = 0;
    double newx, newy;
    while (!pi.isDone()) {
        switch (pi.currentSegment(coords)) {
        case PathIterator.SEG_MOVETO:
            Curve.insertLine(curves, curx, cury, movx, movy);
            curx = movx = coords[0];
            cury = movy = coords[1];
            Curve.insertMove(curves, movx, movy);
            break;
        case PathIterator.SEG_LINETO:
            newx = coords[0];
            newy = coords[1];
            Curve.insertLine(curves, curx, cury, newx, newy);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_QUADTO:
            newx = coords[2];
            newy = coords[3];
            Curve.insertQuad(curves, curx, cury, coords);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_CUBICTO:
            newx = coords[4];
            newy = coords[5];
            Curve.insertCubic(curves, curx, cury, coords);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_CLOSE:
            Curve.insertLine(curves, curx, cury, movx, movy);
            curx = movx;
            cury = movy;
            break;
        }
        pi.next();
    }
    Curve.insertLine(curves, curx, cury, movx, movy);
    AreaOp operator;
    if (windingRule == PathIterator.WIND_EVEN_ODD) {
        operator = new AreaOp.EOWindOp();
    } else {
        operator = new AreaOp.NZWindOp();
    }
    return operator.calculate(curves, EmptyCurves);
}
 
Example 5
Source File: Area.java    From jdk8u_jdk with GNU General Public License v2.0 4 votes vote down vote up
private static Vector pathToCurves(PathIterator pi) {
    Vector curves = new Vector();
    int windingRule = pi.getWindingRule();
    // coords array is big enough for holding:
    //     coordinates returned from currentSegment (6)
    //     OR
    //         two subdivided quadratic curves (2+4+4=10)
    //         AND
    //             0-1 horizontal splitting parameters
    //             OR
    //             2 parametric equation derivative coefficients
    //     OR
    //         three subdivided cubic curves (2+6+6+6=20)
    //         AND
    //             0-2 horizontal splitting parameters
    //             OR
    //             3 parametric equation derivative coefficients
    double coords[] = new double[23];
    double movx = 0, movy = 0;
    double curx = 0, cury = 0;
    double newx, newy;
    while (!pi.isDone()) {
        switch (pi.currentSegment(coords)) {
        case PathIterator.SEG_MOVETO:
            Curve.insertLine(curves, curx, cury, movx, movy);
            curx = movx = coords[0];
            cury = movy = coords[1];
            Curve.insertMove(curves, movx, movy);
            break;
        case PathIterator.SEG_LINETO:
            newx = coords[0];
            newy = coords[1];
            Curve.insertLine(curves, curx, cury, newx, newy);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_QUADTO:
            newx = coords[2];
            newy = coords[3];
            Curve.insertQuad(curves, curx, cury, coords);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_CUBICTO:
            newx = coords[4];
            newy = coords[5];
            Curve.insertCubic(curves, curx, cury, coords);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_CLOSE:
            Curve.insertLine(curves, curx, cury, movx, movy);
            curx = movx;
            cury = movy;
            break;
        }
        pi.next();
    }
    Curve.insertLine(curves, curx, cury, movx, movy);
    AreaOp operator;
    if (windingRule == PathIterator.WIND_EVEN_ODD) {
        operator = new AreaOp.EOWindOp();
    } else {
        operator = new AreaOp.NZWindOp();
    }
    return operator.calculate(curves, EmptyCurves);
}
 
Example 6
Source File: Area.java    From openjdk-8 with GNU General Public License v2.0 4 votes vote down vote up
private static Vector pathToCurves(PathIterator pi) {
    Vector curves = new Vector();
    int windingRule = pi.getWindingRule();
    // coords array is big enough for holding:
    //     coordinates returned from currentSegment (6)
    //     OR
    //         two subdivided quadratic curves (2+4+4=10)
    //         AND
    //             0-1 horizontal splitting parameters
    //             OR
    //             2 parametric equation derivative coefficients
    //     OR
    //         three subdivided cubic curves (2+6+6+6=20)
    //         AND
    //             0-2 horizontal splitting parameters
    //             OR
    //             3 parametric equation derivative coefficients
    double coords[] = new double[23];
    double movx = 0, movy = 0;
    double curx = 0, cury = 0;
    double newx, newy;
    while (!pi.isDone()) {
        switch (pi.currentSegment(coords)) {
        case PathIterator.SEG_MOVETO:
            Curve.insertLine(curves, curx, cury, movx, movy);
            curx = movx = coords[0];
            cury = movy = coords[1];
            Curve.insertMove(curves, movx, movy);
            break;
        case PathIterator.SEG_LINETO:
            newx = coords[0];
            newy = coords[1];
            Curve.insertLine(curves, curx, cury, newx, newy);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_QUADTO:
            newx = coords[2];
            newy = coords[3];
            Curve.insertQuad(curves, curx, cury, coords);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_CUBICTO:
            newx = coords[4];
            newy = coords[5];
            Curve.insertCubic(curves, curx, cury, coords);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_CLOSE:
            Curve.insertLine(curves, curx, cury, movx, movy);
            curx = movx;
            cury = movy;
            break;
        }
        pi.next();
    }
    Curve.insertLine(curves, curx, cury, movx, movy);
    AreaOp operator;
    if (windingRule == PathIterator.WIND_EVEN_ODD) {
        operator = new AreaOp.EOWindOp();
    } else {
        operator = new AreaOp.NZWindOp();
    }
    return operator.calculate(curves, EmptyCurves);
}
 
Example 7
Source File: Area.java    From openjdk-8-source with GNU General Public License v2.0 4 votes vote down vote up
private static Vector pathToCurves(PathIterator pi) {
    Vector curves = new Vector();
    int windingRule = pi.getWindingRule();
    // coords array is big enough for holding:
    //     coordinates returned from currentSegment (6)
    //     OR
    //         two subdivided quadratic curves (2+4+4=10)
    //         AND
    //             0-1 horizontal splitting parameters
    //             OR
    //             2 parametric equation derivative coefficients
    //     OR
    //         three subdivided cubic curves (2+6+6+6=20)
    //         AND
    //             0-2 horizontal splitting parameters
    //             OR
    //             3 parametric equation derivative coefficients
    double coords[] = new double[23];
    double movx = 0, movy = 0;
    double curx = 0, cury = 0;
    double newx, newy;
    while (!pi.isDone()) {
        switch (pi.currentSegment(coords)) {
        case PathIterator.SEG_MOVETO:
            Curve.insertLine(curves, curx, cury, movx, movy);
            curx = movx = coords[0];
            cury = movy = coords[1];
            Curve.insertMove(curves, movx, movy);
            break;
        case PathIterator.SEG_LINETO:
            newx = coords[0];
            newy = coords[1];
            Curve.insertLine(curves, curx, cury, newx, newy);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_QUADTO:
            newx = coords[2];
            newy = coords[3];
            Curve.insertQuad(curves, curx, cury, coords);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_CUBICTO:
            newx = coords[4];
            newy = coords[5];
            Curve.insertCubic(curves, curx, cury, coords);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_CLOSE:
            Curve.insertLine(curves, curx, cury, movx, movy);
            curx = movx;
            cury = movy;
            break;
        }
        pi.next();
    }
    Curve.insertLine(curves, curx, cury, movx, movy);
    AreaOp operator;
    if (windingRule == PathIterator.WIND_EVEN_ODD) {
        operator = new AreaOp.EOWindOp();
    } else {
        operator = new AreaOp.NZWindOp();
    }
    return operator.calculate(curves, EmptyCurves);
}
 
Example 8
Source File: Area.java    From hottub with GNU General Public License v2.0 4 votes vote down vote up
private static Vector pathToCurves(PathIterator pi) {
    Vector curves = new Vector();
    int windingRule = pi.getWindingRule();
    // coords array is big enough for holding:
    //     coordinates returned from currentSegment (6)
    //     OR
    //         two subdivided quadratic curves (2+4+4=10)
    //         AND
    //             0-1 horizontal splitting parameters
    //             OR
    //             2 parametric equation derivative coefficients
    //     OR
    //         three subdivided cubic curves (2+6+6+6=20)
    //         AND
    //             0-2 horizontal splitting parameters
    //             OR
    //             3 parametric equation derivative coefficients
    double coords[] = new double[23];
    double movx = 0, movy = 0;
    double curx = 0, cury = 0;
    double newx, newy;
    while (!pi.isDone()) {
        switch (pi.currentSegment(coords)) {
        case PathIterator.SEG_MOVETO:
            Curve.insertLine(curves, curx, cury, movx, movy);
            curx = movx = coords[0];
            cury = movy = coords[1];
            Curve.insertMove(curves, movx, movy);
            break;
        case PathIterator.SEG_LINETO:
            newx = coords[0];
            newy = coords[1];
            Curve.insertLine(curves, curx, cury, newx, newy);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_QUADTO:
            newx = coords[2];
            newy = coords[3];
            Curve.insertQuad(curves, curx, cury, coords);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_CUBICTO:
            newx = coords[4];
            newy = coords[5];
            Curve.insertCubic(curves, curx, cury, coords);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_CLOSE:
            Curve.insertLine(curves, curx, cury, movx, movy);
            curx = movx;
            cury = movy;
            break;
        }
        pi.next();
    }
    Curve.insertLine(curves, curx, cury, movx, movy);
    AreaOp operator;
    if (windingRule == PathIterator.WIND_EVEN_ODD) {
        operator = new AreaOp.EOWindOp();
    } else {
        operator = new AreaOp.NZWindOp();
    }
    return operator.calculate(curves, EmptyCurves);
}
 
Example 9
Source File: Area.java    From Java8CN with Apache License 2.0 4 votes vote down vote up
private static Vector pathToCurves(PathIterator pi) {
    Vector curves = new Vector();
    int windingRule = pi.getWindingRule();
    // coords array is big enough for holding:
    //     coordinates returned from currentSegment (6)
    //     OR
    //         two subdivided quadratic curves (2+4+4=10)
    //         AND
    //             0-1 horizontal splitting parameters
    //             OR
    //             2 parametric equation derivative coefficients
    //     OR
    //         three subdivided cubic curves (2+6+6+6=20)
    //         AND
    //             0-2 horizontal splitting parameters
    //             OR
    //             3 parametric equation derivative coefficients
    double coords[] = new double[23];
    double movx = 0, movy = 0;
    double curx = 0, cury = 0;
    double newx, newy;
    while (!pi.isDone()) {
        switch (pi.currentSegment(coords)) {
        case PathIterator.SEG_MOVETO:
            Curve.insertLine(curves, curx, cury, movx, movy);
            curx = movx = coords[0];
            cury = movy = coords[1];
            Curve.insertMove(curves, movx, movy);
            break;
        case PathIterator.SEG_LINETO:
            newx = coords[0];
            newy = coords[1];
            Curve.insertLine(curves, curx, cury, newx, newy);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_QUADTO:
            newx = coords[2];
            newy = coords[3];
            Curve.insertQuad(curves, curx, cury, coords);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_CUBICTO:
            newx = coords[4];
            newy = coords[5];
            Curve.insertCubic(curves, curx, cury, coords);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_CLOSE:
            Curve.insertLine(curves, curx, cury, movx, movy);
            curx = movx;
            cury = movy;
            break;
        }
        pi.next();
    }
    Curve.insertLine(curves, curx, cury, movx, movy);
    AreaOp operator;
    if (windingRule == PathIterator.WIND_EVEN_ODD) {
        operator = new AreaOp.EOWindOp();
    } else {
        operator = new AreaOp.NZWindOp();
    }
    return operator.calculate(curves, EmptyCurves);
}
 
Example 10
Source File: Area.java    From jdk1.8-source-analysis with Apache License 2.0 4 votes vote down vote up
private static Vector pathToCurves(PathIterator pi) {
    Vector curves = new Vector();
    int windingRule = pi.getWindingRule();
    // coords array is big enough for holding:
    //     coordinates returned from currentSegment (6)
    //     OR
    //         two subdivided quadratic curves (2+4+4=10)
    //         AND
    //             0-1 horizontal splitting parameters
    //             OR
    //             2 parametric equation derivative coefficients
    //     OR
    //         three subdivided cubic curves (2+6+6+6=20)
    //         AND
    //             0-2 horizontal splitting parameters
    //             OR
    //             3 parametric equation derivative coefficients
    double coords[] = new double[23];
    double movx = 0, movy = 0;
    double curx = 0, cury = 0;
    double newx, newy;
    while (!pi.isDone()) {
        switch (pi.currentSegment(coords)) {
        case PathIterator.SEG_MOVETO:
            Curve.insertLine(curves, curx, cury, movx, movy);
            curx = movx = coords[0];
            cury = movy = coords[1];
            Curve.insertMove(curves, movx, movy);
            break;
        case PathIterator.SEG_LINETO:
            newx = coords[0];
            newy = coords[1];
            Curve.insertLine(curves, curx, cury, newx, newy);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_QUADTO:
            newx = coords[2];
            newy = coords[3];
            Curve.insertQuad(curves, curx, cury, coords);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_CUBICTO:
            newx = coords[4];
            newy = coords[5];
            Curve.insertCubic(curves, curx, cury, coords);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_CLOSE:
            Curve.insertLine(curves, curx, cury, movx, movy);
            curx = movx;
            cury = movy;
            break;
        }
        pi.next();
    }
    Curve.insertLine(curves, curx, cury, movx, movy);
    AreaOp operator;
    if (windingRule == PathIterator.WIND_EVEN_ODD) {
        operator = new AreaOp.EOWindOp();
    } else {
        operator = new AreaOp.NZWindOp();
    }
    return operator.calculate(curves, EmptyCurves);
}
 
Example 11
Source File: Area.java    From openjdk-jdk9 with GNU General Public License v2.0 4 votes vote down vote up
private static Vector<Curve> pathToCurves(PathIterator pi) {
    Vector<Curve> curves = new Vector<>();
    int windingRule = pi.getWindingRule();
    // coords array is big enough for holding:
    //     coordinates returned from currentSegment (6)
    //     OR
    //         two subdivided quadratic curves (2+4+4=10)
    //         AND
    //             0-1 horizontal splitting parameters
    //             OR
    //             2 parametric equation derivative coefficients
    //     OR
    //         three subdivided cubic curves (2+6+6+6=20)
    //         AND
    //             0-2 horizontal splitting parameters
    //             OR
    //             3 parametric equation derivative coefficients
    double coords[] = new double[23];
    double movx = 0, movy = 0;
    double curx = 0, cury = 0;
    double newx, newy;
    while (!pi.isDone()) {
        switch (pi.currentSegment(coords)) {
        case PathIterator.SEG_MOVETO:
            Curve.insertLine(curves, curx, cury, movx, movy);
            curx = movx = coords[0];
            cury = movy = coords[1];
            Curve.insertMove(curves, movx, movy);
            break;
        case PathIterator.SEG_LINETO:
            newx = coords[0];
            newy = coords[1];
            Curve.insertLine(curves, curx, cury, newx, newy);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_QUADTO:
            newx = coords[2];
            newy = coords[3];
            Curve.insertQuad(curves, curx, cury, coords);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_CUBICTO:
            newx = coords[4];
            newy = coords[5];
            Curve.insertCubic(curves, curx, cury, coords);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_CLOSE:
            Curve.insertLine(curves, curx, cury, movx, movy);
            curx = movx;
            cury = movy;
            break;
        }
        pi.next();
    }
    Curve.insertLine(curves, curx, cury, movx, movy);
    AreaOp operator;
    if (windingRule == PathIterator.WIND_EVEN_ODD) {
        operator = new AreaOp.EOWindOp();
    } else {
        operator = new AreaOp.NZWindOp();
    }
    return operator.calculate(curves, EmptyCurves);
}
 
Example 12
Source File: Area.java    From Bytecoder with Apache License 2.0 4 votes vote down vote up
private static Vector<Curve> pathToCurves(PathIterator pi) {
    Vector<Curve> curves = new Vector<>();
    int windingRule = pi.getWindingRule();
    // coords array is big enough for holding:
    //     coordinates returned from currentSegment (6)
    //     OR
    //         two subdivided quadratic curves (2+4+4=10)
    //         AND
    //             0-1 horizontal splitting parameters
    //             OR
    //             2 parametric equation derivative coefficients
    //     OR
    //         three subdivided cubic curves (2+6+6+6=20)
    //         AND
    //             0-2 horizontal splitting parameters
    //             OR
    //             3 parametric equation derivative coefficients
    double[] coords = new double[23];
    double movx = 0, movy = 0;
    double curx = 0, cury = 0;
    double newx, newy;
    while (!pi.isDone()) {
        switch (pi.currentSegment(coords)) {
        case PathIterator.SEG_MOVETO:
            Curve.insertLine(curves, curx, cury, movx, movy);
            curx = movx = coords[0];
            cury = movy = coords[1];
            Curve.insertMove(curves, movx, movy);
            break;
        case PathIterator.SEG_LINETO:
            newx = coords[0];
            newy = coords[1];
            Curve.insertLine(curves, curx, cury, newx, newy);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_QUADTO:
            newx = coords[2];
            newy = coords[3];
            Curve.insertQuad(curves, curx, cury, coords);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_CUBICTO:
            newx = coords[4];
            newy = coords[5];
            Curve.insertCubic(curves, curx, cury, coords);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_CLOSE:
            Curve.insertLine(curves, curx, cury, movx, movy);
            curx = movx;
            cury = movy;
            break;
        }
        pi.next();
    }
    Curve.insertLine(curves, curx, cury, movx, movy);
    AreaOp operator;
    if (windingRule == PathIterator.WIND_EVEN_ODD) {
        operator = new AreaOp.EOWindOp();
    } else {
        operator = new AreaOp.NZWindOp();
    }
    return operator.calculate(curves, EmptyCurves);
}
 
Example 13
Source File: Area.java    From openjdk-jdk8u-backup with GNU General Public License v2.0 4 votes vote down vote up
private static Vector pathToCurves(PathIterator pi) {
    Vector curves = new Vector();
    int windingRule = pi.getWindingRule();
    // coords array is big enough for holding:
    //     coordinates returned from currentSegment (6)
    //     OR
    //         two subdivided quadratic curves (2+4+4=10)
    //         AND
    //             0-1 horizontal splitting parameters
    //             OR
    //             2 parametric equation derivative coefficients
    //     OR
    //         three subdivided cubic curves (2+6+6+6=20)
    //         AND
    //             0-2 horizontal splitting parameters
    //             OR
    //             3 parametric equation derivative coefficients
    double coords[] = new double[23];
    double movx = 0, movy = 0;
    double curx = 0, cury = 0;
    double newx, newy;
    while (!pi.isDone()) {
        switch (pi.currentSegment(coords)) {
        case PathIterator.SEG_MOVETO:
            Curve.insertLine(curves, curx, cury, movx, movy);
            curx = movx = coords[0];
            cury = movy = coords[1];
            Curve.insertMove(curves, movx, movy);
            break;
        case PathIterator.SEG_LINETO:
            newx = coords[0];
            newy = coords[1];
            Curve.insertLine(curves, curx, cury, newx, newy);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_QUADTO:
            newx = coords[2];
            newy = coords[3];
            Curve.insertQuad(curves, curx, cury, coords);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_CUBICTO:
            newx = coords[4];
            newy = coords[5];
            Curve.insertCubic(curves, curx, cury, coords);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_CLOSE:
            Curve.insertLine(curves, curx, cury, movx, movy);
            curx = movx;
            cury = movy;
            break;
        }
        pi.next();
    }
    Curve.insertLine(curves, curx, cury, movx, movy);
    AreaOp operator;
    if (windingRule == PathIterator.WIND_EVEN_ODD) {
        operator = new AreaOp.EOWindOp();
    } else {
        operator = new AreaOp.NZWindOp();
    }
    return operator.calculate(curves, EmptyCurves);
}
 
Example 14
Source File: Area.java    From openjdk-jdk8u with GNU General Public License v2.0 4 votes vote down vote up
private static Vector pathToCurves(PathIterator pi) {
    Vector curves = new Vector();
    int windingRule = pi.getWindingRule();
    // coords array is big enough for holding:
    //     coordinates returned from currentSegment (6)
    //     OR
    //         two subdivided quadratic curves (2+4+4=10)
    //         AND
    //             0-1 horizontal splitting parameters
    //             OR
    //             2 parametric equation derivative coefficients
    //     OR
    //         three subdivided cubic curves (2+6+6+6=20)
    //         AND
    //             0-2 horizontal splitting parameters
    //             OR
    //             3 parametric equation derivative coefficients
    double coords[] = new double[23];
    double movx = 0, movy = 0;
    double curx = 0, cury = 0;
    double newx, newy;
    while (!pi.isDone()) {
        switch (pi.currentSegment(coords)) {
        case PathIterator.SEG_MOVETO:
            Curve.insertLine(curves, curx, cury, movx, movy);
            curx = movx = coords[0];
            cury = movy = coords[1];
            Curve.insertMove(curves, movx, movy);
            break;
        case PathIterator.SEG_LINETO:
            newx = coords[0];
            newy = coords[1];
            Curve.insertLine(curves, curx, cury, newx, newy);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_QUADTO:
            newx = coords[2];
            newy = coords[3];
            Curve.insertQuad(curves, curx, cury, coords);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_CUBICTO:
            newx = coords[4];
            newy = coords[5];
            Curve.insertCubic(curves, curx, cury, coords);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_CLOSE:
            Curve.insertLine(curves, curx, cury, movx, movy);
            curx = movx;
            cury = movy;
            break;
        }
        pi.next();
    }
    Curve.insertLine(curves, curx, cury, movx, movy);
    AreaOp operator;
    if (windingRule == PathIterator.WIND_EVEN_ODD) {
        operator = new AreaOp.EOWindOp();
    } else {
        operator = new AreaOp.NZWindOp();
    }
    return operator.calculate(curves, EmptyCurves);
}
 
Example 15
Source File: Area.java    From JDKSourceCode1.8 with MIT License 4 votes vote down vote up
private static Vector pathToCurves(PathIterator pi) {
    Vector curves = new Vector();
    int windingRule = pi.getWindingRule();
    // coords array is big enough for holding:
    //     coordinates returned from currentSegment (6)
    //     OR
    //         two subdivided quadratic curves (2+4+4=10)
    //         AND
    //             0-1 horizontal splitting parameters
    //             OR
    //             2 parametric equation derivative coefficients
    //     OR
    //         three subdivided cubic curves (2+6+6+6=20)
    //         AND
    //             0-2 horizontal splitting parameters
    //             OR
    //             3 parametric equation derivative coefficients
    double coords[] = new double[23];
    double movx = 0, movy = 0;
    double curx = 0, cury = 0;
    double newx, newy;
    while (!pi.isDone()) {
        switch (pi.currentSegment(coords)) {
        case PathIterator.SEG_MOVETO:
            Curve.insertLine(curves, curx, cury, movx, movy);
            curx = movx = coords[0];
            cury = movy = coords[1];
            Curve.insertMove(curves, movx, movy);
            break;
        case PathIterator.SEG_LINETO:
            newx = coords[0];
            newy = coords[1];
            Curve.insertLine(curves, curx, cury, newx, newy);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_QUADTO:
            newx = coords[2];
            newy = coords[3];
            Curve.insertQuad(curves, curx, cury, coords);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_CUBICTO:
            newx = coords[4];
            newy = coords[5];
            Curve.insertCubic(curves, curx, cury, coords);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_CLOSE:
            Curve.insertLine(curves, curx, cury, movx, movy);
            curx = movx;
            cury = movy;
            break;
        }
        pi.next();
    }
    Curve.insertLine(curves, curx, cury, movx, movy);
    AreaOp operator;
    if (windingRule == PathIterator.WIND_EVEN_ODD) {
        operator = new AreaOp.EOWindOp();
    } else {
        operator = new AreaOp.NZWindOp();
    }
    return operator.calculate(curves, EmptyCurves);
}
 
Example 16
Source File: Area.java    From jdk8u60 with GNU General Public License v2.0 4 votes vote down vote up
private static Vector pathToCurves(PathIterator pi) {
    Vector curves = new Vector();
    int windingRule = pi.getWindingRule();
    // coords array is big enough for holding:
    //     coordinates returned from currentSegment (6)
    //     OR
    //         two subdivided quadratic curves (2+4+4=10)
    //         AND
    //             0-1 horizontal splitting parameters
    //             OR
    //             2 parametric equation derivative coefficients
    //     OR
    //         three subdivided cubic curves (2+6+6+6=20)
    //         AND
    //             0-2 horizontal splitting parameters
    //             OR
    //             3 parametric equation derivative coefficients
    double coords[] = new double[23];
    double movx = 0, movy = 0;
    double curx = 0, cury = 0;
    double newx, newy;
    while (!pi.isDone()) {
        switch (pi.currentSegment(coords)) {
        case PathIterator.SEG_MOVETO:
            Curve.insertLine(curves, curx, cury, movx, movy);
            curx = movx = coords[0];
            cury = movy = coords[1];
            Curve.insertMove(curves, movx, movy);
            break;
        case PathIterator.SEG_LINETO:
            newx = coords[0];
            newy = coords[1];
            Curve.insertLine(curves, curx, cury, newx, newy);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_QUADTO:
            newx = coords[2];
            newy = coords[3];
            Curve.insertQuad(curves, curx, cury, coords);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_CUBICTO:
            newx = coords[4];
            newy = coords[5];
            Curve.insertCubic(curves, curx, cury, coords);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_CLOSE:
            Curve.insertLine(curves, curx, cury, movx, movy);
            curx = movx;
            cury = movy;
            break;
        }
        pi.next();
    }
    Curve.insertLine(curves, curx, cury, movx, movy);
    AreaOp operator;
    if (windingRule == PathIterator.WIND_EVEN_ODD) {
        operator = new AreaOp.EOWindOp();
    } else {
        operator = new AreaOp.NZWindOp();
    }
    return operator.calculate(curves, EmptyCurves);
}
 
Example 17
Source File: Area.java    From TencentKona-8 with GNU General Public License v2.0 4 votes vote down vote up
private static Vector pathToCurves(PathIterator pi) {
    Vector curves = new Vector();
    int windingRule = pi.getWindingRule();
    // coords array is big enough for holding:
    //     coordinates returned from currentSegment (6)
    //     OR
    //         two subdivided quadratic curves (2+4+4=10)
    //         AND
    //             0-1 horizontal splitting parameters
    //             OR
    //             2 parametric equation derivative coefficients
    //     OR
    //         three subdivided cubic curves (2+6+6+6=20)
    //         AND
    //             0-2 horizontal splitting parameters
    //             OR
    //             3 parametric equation derivative coefficients
    double coords[] = new double[23];
    double movx = 0, movy = 0;
    double curx = 0, cury = 0;
    double newx, newy;
    while (!pi.isDone()) {
        switch (pi.currentSegment(coords)) {
        case PathIterator.SEG_MOVETO:
            Curve.insertLine(curves, curx, cury, movx, movy);
            curx = movx = coords[0];
            cury = movy = coords[1];
            Curve.insertMove(curves, movx, movy);
            break;
        case PathIterator.SEG_LINETO:
            newx = coords[0];
            newy = coords[1];
            Curve.insertLine(curves, curx, cury, newx, newy);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_QUADTO:
            newx = coords[2];
            newy = coords[3];
            Curve.insertQuad(curves, curx, cury, coords);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_CUBICTO:
            newx = coords[4];
            newy = coords[5];
            Curve.insertCubic(curves, curx, cury, coords);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_CLOSE:
            Curve.insertLine(curves, curx, cury, movx, movy);
            curx = movx;
            cury = movy;
            break;
        }
        pi.next();
    }
    Curve.insertLine(curves, curx, cury, movx, movy);
    AreaOp operator;
    if (windingRule == PathIterator.WIND_EVEN_ODD) {
        operator = new AreaOp.EOWindOp();
    } else {
        operator = new AreaOp.NZWindOp();
    }
    return operator.calculate(curves, EmptyCurves);
}
 
Example 18
Source File: Area.java    From dragonwell8_jdk with GNU General Public License v2.0 4 votes vote down vote up
private static Vector pathToCurves(PathIterator pi) {
    Vector curves = new Vector();
    int windingRule = pi.getWindingRule();
    // coords array is big enough for holding:
    //     coordinates returned from currentSegment (6)
    //     OR
    //         two subdivided quadratic curves (2+4+4=10)
    //         AND
    //             0-1 horizontal splitting parameters
    //             OR
    //             2 parametric equation derivative coefficients
    //     OR
    //         three subdivided cubic curves (2+6+6+6=20)
    //         AND
    //             0-2 horizontal splitting parameters
    //             OR
    //             3 parametric equation derivative coefficients
    double coords[] = new double[23];
    double movx = 0, movy = 0;
    double curx = 0, cury = 0;
    double newx, newy;
    while (!pi.isDone()) {
        switch (pi.currentSegment(coords)) {
        case PathIterator.SEG_MOVETO:
            Curve.insertLine(curves, curx, cury, movx, movy);
            curx = movx = coords[0];
            cury = movy = coords[1];
            Curve.insertMove(curves, movx, movy);
            break;
        case PathIterator.SEG_LINETO:
            newx = coords[0];
            newy = coords[1];
            Curve.insertLine(curves, curx, cury, newx, newy);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_QUADTO:
            newx = coords[2];
            newy = coords[3];
            Curve.insertQuad(curves, curx, cury, coords);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_CUBICTO:
            newx = coords[4];
            newy = coords[5];
            Curve.insertCubic(curves, curx, cury, coords);
            curx = newx;
            cury = newy;
            break;
        case PathIterator.SEG_CLOSE:
            Curve.insertLine(curves, curx, cury, movx, movy);
            curx = movx;
            cury = movy;
            break;
        }
        pi.next();
    }
    Curve.insertLine(curves, curx, cury, movx, movy);
    AreaOp operator;
    if (windingRule == PathIterator.WIND_EVEN_ODD) {
        operator = new AreaOp.EOWindOp();
    } else {
        operator = new AreaOp.NZWindOp();
    }
    return operator.calculate(curves, EmptyCurves);
}